Tubular drainage device

ABSTRACT

A medical device for draining a fluid from the body of a patient includes a tubular member having an open distal end that resides interiorly of the body of a patient and a proximal end that extends exteriorly of the body of the patient. The tubular member has an inner surface extending between the distal end and the proximal end, wherein the inner surface defines a lumen. An interior member is disposed in the lumen and extends along a length of the inner surface. The interior member is engaged with the inner surface such that a chamber is defined therebetween. A conduit is engaged with the tubular member for transmission of an inflation fluid to selectively vary a dimension of the chamber for freeing clogged debris in the lumen.

This application is a continuation of U.S. patent application Ser. No.13/302,623, filed on Nov. 22, 2011, which issued as U.S. Pat. No.9,302,031 on Apr. 5, 2016. This prior application is hereby incorporatedby reference herein.

BACKGROUND

The present disclosure relates generally to the field of medicaldevices, and more particularly, to a tubular device for use in drainingfluids from the body of a patient.

In the human body, the lungs are surrounded by the pleura. The pleura isa serous membrane which folds back upon itself to form a two membranestructure. The two membranes are known as the parietal pleura and thevisceral pleura, respectively. The parietal (outer) pleura lines thechest wall, while the visceral (inner) pleura surrounds the lung. Thespace between the two pleurae layers is known as the pleural space orcavity, which space typically contains a thin layer of pleural fluid.This thin layer of fluid provides lubrication to enable the pluraelayers to smoothly slide over one another during respiration.

Pleural effusion refers to a condition that occurs when an excess offluid accumulates in the pleural space. Typically, such accumulationresults from chest trauma experienced by the patient. The collection ofair in the pleural space results in a condition commonly referred to aspneumothorax. The collection of blood in the pleural space results in acondition commonly referred to as hemothorax. Other fluids that maycollect in the pleural space include serous fluid (hydrothorax), chyle(chylothorax), and pus (pyothorax). The presence of excessive amounts offluids in the pleural space impairs the breathing ability of the patientby limiting the ability of the lungs to expand during inhalation.

In order to drain excess fluid, a chest tube may be inserted into thepleural space. Often the chest tube is inserted utilizing the well-knownSeldinger technique. In the Seldinger technique, a needle is initiallyadvanced into the pleural space. A wire guide is inserted through a boreof the needle, and the needle is thereafter removed, leaving the distalend of the wire guide positioned in the pleural space. A series oftapered dilators (such as three) are sequentially advanced (small tolarge) over the wire guide to dilate the tissue of the chest wall, andform an opening, or stoma, of desired size. Alternatively, an inflatableballoon may be inserted to dilate the tissue. After removal of thedilator, the chest tube is placed over the wire guide, and the distalend of the tube is directed into the pleural space. Further discussionof the insertion of a chest tube into the pleural space is provided inU.S. Pat. Publ. No. 2011/0152874, incorporated by reference herein.

During drainage of fluid through the chest tube, blood or other fluidscan clot or otherwise accumulate in the lumen of the tube. When thisoccurs, the flow of fluids through the chest tube becomes partially orfully blocked. Consequently, since the fluid cannot fully pass throughthe tube, excess fluid may build up in the pleural space. The build-upof excess fluid in the pleural space can restrict the full expansion ofthe lungs and lead to deleterious consequences to the patient, includingpotential death. When the chest tube is implanted and sterile, the enduser can at times manipulate the chest tube to remove a blood clot,etc., such as by squeezing the chest tube, bending the chest tube atseveral points, and/or sliding while squeezing the chest tube. The chesttube can be partially withdrawn in order to gain external access to theblood clot. However, this action violates the sterile internalenvironment of the chest tube, making the treated area more susceptibleto infection. Further, the seal between the chest tube and the drainagesystem is broken, which can increase the risk of losing thephysiological negative pressure inside the chest.

It would be desirable to provide a drainage device that includes meansfor effectively eliminating blocking or clogging of the device. It wouldbe desirable if such action occurs while maintaining the drainage deviceimplanted within the patient in order to maintain a sterile environment.

SUMMARY

The present invention addresses the shortcomings of the prior art. Inone form, the invention is directed to a medical device for draining afluid from the body of a patient. The medical device includes a tubularmember configured to have a distal end residing interiorly of the bodyof a patient and a proximal end extending exteriorly of the body of thepatient. The distal end has an opening for transmission of the fluid.The tubular member has an inner surface extending between the distal endand the proximal end, wherein the inner surface defines a lumen. Aninterior member is disposed in the lumen and extends along a length ofthe inner surface. The interior member is engaged with the inner surfacesuch that a chamber is defined therebetween. A conduit is engaged withthe tubular member for transmission of an inflation fluid forselectively varying a dimension of the chamber.

In another form thereof, the invention is directed to a drainage system.The drainage system comprises a tubular member configured to have adistal end residing within an interior body space of a patient and aproximal end extending outside of the body of the patient. The distalend has an opening for receiving a body fluid from the body space. Thetubular member has an inner surface extending between the distal end andthe proximal end, wherein the inner surface defines a lumen. An interiormember is disposed in the lumen and extends along a length of the innersurface. The interior member is engaged with the inner surface such thata substantially air-tight chamber is defined therebetween. A source ofan inflation fluid is in communication with the chamber.

In still another form thereof, the invention is directed to a method fordraining a body fluid from an interior body space of a patient. Adrainage tube is positioned for receiving the body fluid. The drainagetube comprises a tubular member having a distal end residing within theinterior body space of the patient and a proximal end extending outsideof the body of the patient. The tubular member has an inner surfaceextending between the distal end and the proximal end, wherein the innersurface defines a lumen. An interior member is disposed in the lumen andextends along a length of the inner surface. The interior member isengaged with the inner surface such that a chamber is definedtherebetween. A conduit is engaged with the tubular member fortransmission of a fluid for selectively varying a dimension of thechamber. An amount of fluid is established in the chamber such that thechamber has a first thickness. The amount of fluid in the chamber isadjusted such that the chamber has a second thickness. A negativepressure is drawn through the proximal end of the tube to draw the bodyfluid from the body space through the drainage tube.

BRIEF DESCRIPTIONS OF THE DRAWINGS

FIG. 1 illustrates a side view of a tubular drainage device, accordingto an embodiment of the invention;

FIG. 2A illustrates a longitudinal sectional view of the tubulardrainage device of FIG. 1, wherein an inflation fluid has beenintroduced to define a chamber between the inner surface of the tubularmember and an interior member;

FIG. 2B illustrates a longitudinal sectional view of the tubulardrainage device as in FIG. 2A, wherein the inflation fluid has beenevacuated to collapse the chamber;

FIG. 3A is an enlarged cross-sectional view of the tubular drainagedevice of FIG. 2A, taken along line 3A-3A;

FIG. 3B is an enlarged cross-sectional view of the tubular drainagedevice of FIG. 2B, taken along line 3B-3B; and

FIG. 4 depicts a tubular drainage device positioned for draining thepleural space of a patient.

DETAILED DESCRIPTION OF THE DRAWINGS AND THE PRESENTLY PREFERREDEMBODIMENTS

For the purposes of promoting an understanding of the principles of theinvention, reference will now be made to the embodiments illustrated inthe drawings, and specific language will be used to describe the same.It should nevertheless be understood that no limitation of the scope ofthe invention is thereby intended, such alterations and furthermodifications in the illustrated device, and such further applicationsof the principles of the invention as illustrated therein beingcontemplated as would normally occur to one skilled in the art to whichthe invention relates.

Throughout the specification, when referring to a medical device, or aportion of a medical device, the terms “distal” and “distally” shalldenote a position, direction, or orientation that is generally toward,or in the direction of, the patient when the device is in use. The terms“proximal” and “proximally” shall denote a position, direction, ororientation that is generally away from the patient, or closer to theoperator, during use of the device. It is understood thatlike-referenced numerals are used throughout the Figures to designatesimilar components.

The tubular drainage device described herein can be useful for drainageof vessels, lumens, ducts, spaces, or passageways of the body. Whendiscussion of such vessels, lumens, ducts, spaces, or passageways ismade herein, these terms are used to describe such structures in generalas found in the body of the patient, and are not limited to any oneparticular vessel, lumen, duct, space, passageway, etc.

In the embodiment shown in the figures, the tubular drainage devicecomprises a chest tube 10 for draining fluid from the pleural space. Asstated above, chest tube 10 is only one example of a tubular drainagedevice according to the present invention. Those skilled in the art willappreciate that the tubular drainage device as shown and describedherein will be suitable for use in draining fluid from other vessels,lumens, ducts, spaces, or passageways in the body, with no more thanminor and/or routine modification. Non-limiting additional examplesinclude catheters and surgical drain tubes for draining fluid from otherorifices (besides the chest cavity), endotracheal tubes, feeding tubes,gastric tubes, nephrostomy tubes, biliary tubes, and tubes fordelivering material to or from the alimentary tract.

With particular reference to the non-limiting embodiment shown in thefigures, chest tube 10 comprises a hollow elongated tubular member 12.Hollow elongated tubular member 12 has an exterior surface 32, an innersurface 36, and a lumen 38 extending therethrough. Tubular member 12 hasa proximal end 20 and a distal end 14. Preferably, distal end 14 tapersto open distal tip 15. A hub 30 may be affixed at proximal end 20. Hub30, which may include a Luer connector or other conventional couplingmember used in the medical arts, is provided for coupling chest tube 10to a collection receptacle, such as drainage canister 60. Drainagecatheter 60 is shown schematically in FIG. 4.

As shown in FIGS. 2A and 2B, an interior member 40 extends along tubularmember inner surface 36. In one embodiment, interior member 40 comprisesa thin layer of tubing. Preferably, interior member 40 extends alongall, or substantially all, of the circumference of inner surface 36.Interior member 40 includes a proximal end 42 and a distal end 44.Proximal end 42 and distal end 44 are circumferentially bonded to innersurface 36 of tubular member 12 at respective seals 50, 52, to form asubstantially air-tight chamber 46 that circumferentially extendsbetween interior member 40 and tubular member inner surface 36. Seals50, 52 may comprise any conventional mode of engagement between surfacesin common use in the medical arts, such as an adhesive or a thermalbond. One example of a suitable adhesive comprises a LOCTITE®cyanoacrylate adhesive, available from Henkel Corporation.

One end of a conduit 24 extends through an opening in tubular memberproximal end 20, and communicates with chamber 46. The other end ofconduit 24 communicates with a source 26 of an inflation fluid. Theinflation fluid may be any fluid commonly used in the medical arts forinflating an expandable member, such as air or a saline solution.Chamber 46 (FIGS. 2A, 3A) is formed upon the introduction of theinflation fluid into the space between tubular member 12 and interiormember 40. FIGS. 2B, 3B illustrate the relative positions of tubularmember 12 and interior member 40 prior to introduction of the inflationfluid, and/or following an evacuation of the inflation fluid from thechamber whereby the chamber is collapsed. Inflation fluid may beevacuated from the chamber by any conventional means. If desired, thiscan conveniently be accomplished by conventional use of a stop-cock (notshown) or like device along conduit 24 to create a pathway forcommunication between a negative pressure source (e.g., a syringe) andthe chamber.

Elongated tubular member 12 may be formed of any materials commonlyutilized in the art for forming such tubes. For example, tubular member12 may be formed from a relatively rigid, clear polymer, such aspolyvinylchloride (PVC). Those skilled in the art will appreciate thatother polymers commonly employed for such purposes, such as polyurethaneand polyamide (nylon), may be substituted. Tubular member 12 may haveany dimensions typically provided with conventional chest tubes. Forexample, tubular member 12 may have an outer diameter from about 8 to 36French (0.11 to 0.47 inch) (2.8 to 12 mm), and an inner diameter fromabout 0.043 to 0.33 inch (1.10 to 8.4 mm). The tubular member may have awall thickness of about 0.011 to 0.120 inch (0.28 to 3.05 mm), and mayhave a length from about 18 to 41 cm. In general, smaller French sizechest tubes will have a shorter length, and larger French size tubeswill have a greater length.

Interior member 40 may be formed of the same materials used to formtubular member 12, or alternatively, may be formed from expandablepolymeric materials commonly used in the medical arts. Typically,interior member 40 will comprise a thin layer of this material, and willhave a wall thickness much less than that of the tubular member, such asabout 0.002 inch (0.05 mm). Thus, in one example, tubular member 12 mayhave a wall thickness of about 0.025 inch (0.64 mm), and interior member40 may have a wall thickness of about 0.002 inch (0.05 mm).

Prior to introduction of an inflation fluid into the chamber, interiormember 40 is disposed such that it generally abuts inner surface 36 oftubular member 12, as shown in FIGS. 2B and 3B. In this event, chamber40 has little, if any, radial thickness. Upon introduction of theinflation fluid into chamber 46 as described herein, interior member 40and inner surface 36 are spaced to define the chamber 46, as shown inFIGS. 2A and 3A. At this time, chamber 46 may have a radial thicknessof, for example, about 0.01 to 0.03 inch (0.25 to 0.76 mm).

Those skilled in the art will appreciate that the dimensions describedherein are only examples of suitable dimensions for a chest tube, andthat the tubular member, interior member, and chamber may have greater,or lesser, dimensions than specifically described herein. In addition,those skilled in the art will appreciate that tubes intended for useother than as chest drainage tubes will have dimensions appropriate forsuch intended use. Those skilled in the art are capable of adjusting thedimensions as described herein for such uses, in light of the teachingsof the present invention.

As with conventional chest tubes, tubular member 12 may include one ormore radiopaque stripes (not shown) along a length of the tubularmember. If desired, the tubular member may be provided with ahydrophilic coating along at least the distal portion of its outersurface. Tubular drainage devices are well known in the art, and to theextent not specifically referenced herein, tube 10 may be provided withadditional features known to be provided with such tubes.

Chest tube 10 is configured to provide a fluid path from the pleuralspace to a collection receptacle, such as canister 60 shown in FIG. 4. Avacuum or other negative pressure source 62 can be coupled to thecanister to form a closed-suction drainage system. The negative pressuresource 62 is configured to create low pressure in the drainage canister60 in order to draw fluids out of the pleural space and into thedrainage canister 60 via chest tube 10 in well-known fashion.

Those skilled in the art will appreciate that the chest tube 10 can beused to facilitate the removal of debris, such as, but not limited to,clots formed of blood, mucus, or other bodily fluids, from within thelumen 38 of tubular member 12. During use of the chest tube, such debrismay become adhered to the inner surface of interior member 40, such thatit cannot be easily removed by the suction forces generated by thenegative pressure source. The presence of such debris in the lumenimpedes the flow of fluid to be drained from the body vessel, lumen,duct, space, passageway, etc. Depending upon the size and amount of suchdebris, fluid flow through the tube may be prevented altogether.

The following discussion will describe the use of tube 10 as a chesttube to drain fluid from the pleural space of a patient, and moreparticularly, will describe and illustrate use of the features of tube10 to clear a clot from the lumen of the tube. As noted above, themedical tube need not be a chest tube, and the following example is onlyintended to describe one possible use of tube 10.

FIG. 4 illustrates chest tube 10 positioned in the pleural space of thepatient. Those skilled in the art are aware of numerous suitable methodsfor introducing the distal end of a chest tube into the pleural space.One such method is described in the incorporated-by-reference U.S. Pat.Publ. No. 2011/0152874.

When properly positioned, distal tip 15 of tubular member 12 extendsinto the pleural space 100 that separates lung 102 and intercostalmuscle 108. As shown in FIG. 4, chest tube 10 is positioned between anadjacent pair of ribs 104. Prior to use, the chest tube may be suturedto the skin of the patient in well-known fashion.

An inflation fluid from source 26 is introduced into chamber 46 viaconduit 24 as described. Introduction of a fluid into chamber 46increases the radial thickness, or diameter, of the chamber. As thethickness of chamber 46 is increased, the effective inner diameter ofthe chest tube for passage of body fluids is reduced. Compare, e.g., thecondition of tubular member 12 in FIGS. 2A and 3A wherein the thicknessof chamber 46 is increased, with the condition of the tubular member inFIGS. 2B and 3B, wherein the inflation fluid is evacuated from (or hasnot yet been introduced into) the chamber. As illustrated, chamber 46has only a nominal thickness in FIGS. 2B and 3B, thereby increasing theeffective inner diameter of the chest tube. In FIGS. 2A and 3A, withchamber 46 inflated to its maximum radial diameter, the effective innerdiameter of the chest tube available for passage of body fluid isreduced when compared to FIGS. 2B and 3B.

As discussed above, once a chest tube has been in use for a period oftime, debris drained from the pleural space may build up in thepassageway through the tube. Build-up of such debris may clog thepassageway and prevent further drainage of body fluid therethrough. Anexample of debris D clogging the passageway of a drainage tube is shownin FIG. 2A.

In order to clear this debris, the inflation fluid is evacuated from thechamber. This action deflates chamber 46, thereby increasing theeffective diameter of the chest tube as shown in FIGS. 2B and 3B. As aresult of the increased effective diameter of the tube, the cloggeddebris loosens from its engagement with the surface of the interiormember 40, as shown in FIG. 2B. Once loosened from engagement with thissurface, the debris may be drawn through the chest tube and into thecanister 60 by the suction created by negative pressure source 62.Following removal of the debris, chamber 46 can be reinflated as before,and drainage of fluid from the pleural space is resumed. The process canthen be repeated as necessary in the event of future clogging of thelumen.

As an alternative to the method described above, the inflation/deflationsequence of the chamber can be reversed. In this example, the chambermay be in the deflated condition shown in FIGS. 2B, 3B during normaldrainage operation. As discussed above, this condition provides a largereffective inner diameter of the tube. If the lumen becomes clogged, thechamber is inflated as described above to the condition shown in FIGS.2A, 3A to compact the clogging material. Then, the chamber is deflatedto its original condition by evacuating the inflation fluid, therebyonce again increasing the effective diameter of the lumen. This actionis intended to free at least a portion of the compacted material fromcontact with the inner surface of the interior member 40, and thereby,facilitate removal of the compacted debris by the suction forces asdescribed.

Although it is preferred that interior member 40 extend along virtuallythe entire inner circumference of inner surface 36 to form the air-tightchamber as shown and described, this is not necessarily required in allembodiments. For example, interior member 40 may extend longitudinallyas a strip along all or part of the length of the inner surface, but notnecessarily around the entire inner circumference. In this event, thelongitudinal strip will be adequately sealed to form the chamber, andthe chamber communicates with the source of inflation fluid as describedabove. As a still further alternative, interior member 40 and chamber 46need not necessarily extend the entire length of the inner surface ofthe tubular member. However, it is believed that best results will beachieved when the interior member extends along all, or at leastsubstantially all, of the inner circumference of the inner surface, asshown and described herein.

Drawings in the figures illustrating various embodiments are notnecessarily to scale. Some drawings may have certain details magnifiedfor emphasis, and any different numbers or proportions of parts shouldnot be read as limiting, unless so designated in the present disclosure.Those of skill in the art will appreciate that embodiments not expresslydescribed and/or illustrated herein may be practiced within the scope ofthe present invention. It is therefore intended that the foregoingdetailed description be regarded as illustrative rather than limiting.It should be understood that the following claims, including allequivalents, are intended to define the spirit and scope of thisinvention.

What is claimed is:
 1. A medical device for draining a fluid from thebody of a patient, comprising: a relatively rigid tubular memberconfigured to have a distal end residing interiorly of the body of apatient and a proximal end extending exteriorly of the body of thepatient, said distal end having an opening for transmission of saidfluid, the tubular member having an inner surface extending between saiddistal end and said proximal end, said inner surface defining a lumen;and an interior member disposed in said lumen extending alongsubstantially an entire length of the lumen and, said interior memberengaged with said inner surface such that a chamber is definedtherebetween; and a conduit engaged with said tubular member fortransmission of an inflation fluid for selectively varying a dimensionof said chamber; wherein inflation of said chamber increases a radialthickness of said chamber and reduces an effective size of said lumen,and deflation of said chamber decreases said radial thickness of saidchamber and increases said effective size of said lumen, such that saidchamber has a first substantially uniform cross-sectional area when thechamber is deflated and a second substantially uniform cross-sectionalarea when the chamber is inflated, said first uniform cross-sectionalarea being less than said second uniform cross-sectional area.
 2. Themedical device of claim 1, wherein said interior member extends a lengthof said inner surface.
 3. The medical device of claim 2, wherein saidtubular member inner surface has a circumference, and said interiormember extends along the circumference of said inner surface.
 4. Themedical device of claim 3, wherein said inner surface has a proximal endand a distal end, further comprising a circumferential seal between saidinner surface proximal end and a proximal end of said interior member,and a circumferential seal between said inner surface distal end and adistal end of said interior member.
 5. The medical device of claim 1,further comprising said tubular member having an outer surface with adiameter; wherein inflation of said chamber does not change the diameterof the outer surface.
 6. A drainage system comprising: a relativelyrigid tubular member configured to have a distal end residing within aninterior body space of a patient and a proximal end extending outside ofthe body of the patient, said distal end having an opening for receivinga body fluid from said body space, the tubular member having an innersurface extending between said distal end and said proximal end, saidinner surface defining a lumen; an interior member disposed in saidlumen extending substantially an entire length of the lumen and, saidinterior member engaged with said inner surface such that asubstantially air-tight chamber is defined therebetween; and a conduitconfigured to receive a source of inflation fluid so that the inflationfluid is in communication with said chamber; wherein inflation of saidchamber increases a radial thickness of said chamber and reduces aneffective size of said lumen and deflation of said chamber decreasessaid radial thickness of said chamber and increases said effective sizeof said lumen; wherein said lumen has a first uniform diameter when thechamber is deflated and a second uniform diameter when the chamber isinflated, said first uniform diameter being greater than said seconduniform diameter.
 7. The system of claim 6, wherein said interior memberextends a length of said inner surface.
 8. The system of claim 7,wherein said tubular member inner surface has a circumference, and saidinterior member extends along the circumference of said inner surface.9. The system of claim 6, further comprising said tubular member havingan outer surface with a diameter; wherein inflation of said chamber doesnot change the diameter of the outer surface.
 10. The system of claim 6,wherein said inner surface has a diameter and adjusting the amount offluid in said chamber does not change the diameter of the inner surface.11. The system of claim 6, comprising a collection receptacle for saidbody fluid, said collection receptacle in communication with the lumenof the tubular member.
 12. The system of claim 11, further comprising anegative pressure source for drawing said body fluid into saidcollection receptacle.
 13. The system of claim 12, wherein the negativepressure source comprises a vacuum.
 14. The drainage system of claim 6,wherein the interior member comprises a wall thickness which is lessthan a wall thickness of the tubular member.
 15. A method for draining abody fluid from an interior body space of a patient, comprising:positioning a drainage tube for receiving said body fluid, said drainagetube comprising a relatively rigid tubular member having a distal endresiding within said interior body space of the patient and a proximalend extending outside of the body of the patient, the tubular memberhaving an inner surface extending between said distal end and saidproximal end, said inner surface defining a lumen, an interior memberdisposed in said lumen extending along substantially an entire length ofthe lumen and, said interior member engaged with said inner surface suchthat a chamber is defined therebetween, and a conduit engaged with saidtubular member for transmission of a fluid for selectively varying adimension of said chamber; establishing an amount of fluid in saidchamber such that said chamber has a first radial thickness; adjustingthe amount of fluid in said chamber such that said chamber has a secondradial thickness; and drawing a negative pressure through the proximalend of the tube to draw said body fluid from said body space throughsaid drainage tube.
 16. The method of claim 15, wherein said firstradial thickness of said chamber is greater than said second radialthickness, and wherein said adjusting step comprises evacuating fluidfrom said chamber to achieve said chamber second radial thickness. 17.The method of claim 15, wherein said inner surface has a diameter andadjusting the amount of fluid in said chamber does not change thediameter of the inner surface.
 18. The method of claim 15, furthercomprising said tubular member having an outer surface with a diameter;wherein adjusting the amount of fluid in said chamber does not changethe diameter of the outer surface.
 19. The method of claim 15, whereinsaid negative pressure draws said body fluid into a collectionreceptacle.
 20. The method of claim 15, wherein said first radialthickness of said chamber is less than said second radial thickness, andwherein said adjusting step comprises introducing said amount of fluidinto said chamber to achieve said chamber second radial thickness, saidmethod including the further step of evacuating fluid from said chamberuntil said chamber reaches said first radial thickness prior to saidstep of drawing said negative pressure.